NL1001399C2 - Metal niobates and or tantalates, process for their preparation, and further processing thereof into perovskites. - Google Patents

Description

Metal niobates and or tantalates. process for its preparation. as well as the further processing thereof into perovskites.

The present invention relates to highly reactive metal niobates and / or tantalates of the general formula Me (II) A206, respectively. Me (III) A04, in which A = Nb and / or Ta and Me = Mg, Fe, Co, Ni, Cr, Mn, Cd and / or Zn, a process for the preparation thereof, the further processing thereof into perovskites with the general formula A (B'B ") 03, where A = Pb and / or Ba, B '= Mg, Fe, Co, Ni, Cr, Mn, Cd, Ti, Zr and / or 10 Zn and B" = Nb and / or Ta, as well as these perovskites.

Metal niobates and / or tantalates serve, inter alia, as starting materials for the preparation of complex perovskites, which are used as materials for electroceramics. Due to the high dielectric constant, the high electrostriction coefficients and the extremely high quality - especially with the tantalates - lead and resp. barium metal niobates and / or tantalates play an increasingly important role, inter alia as base materials for the preparation of condenser ceramics, electrostriction ceramics (actuators), piezo ceramics and microwave ceramics (e.g. resonators). Such compounds with the perovskite structure have the general formula A (B, B ”) 03, where A = Ba and Pb, B '= Mg, Fe, Co, Ni, Cr, Mn, Cd, Cu, Zn and B "= Nb and Ta (Appl. Phys. Lett., 10 (5), I63-165 (1967)).

Several processes are known for the preparation of complex ferroelectric perovskites with a transition metal of the 5th secondary group (Ta and Nb):

From J. Am. Ceram. Soc. 71 (5). C-250-251 (1988), the mixing of the oxides with a subsequent solid reaction at very high calcination temperatures is known. It is very difficult to prepare phase-pure perovskites with more than 80 µl perovskite phase according to this method. Inevitably, a stable pyrochlorine phase occurs in this solid reaction, which markedly deteriorates the properties of the electroceramics obtained.

From J. Ceram. Soc. 67 (5). 3H ~ 3l4 (1984) is known to previously react Nb205 with MgO in a solid reaction, the subsequent reaction with PbO according to formulas (I) Nb205 + MgO-MgNb206 (columbite). (II) MgNb206 + 3Pb0 - Pb3MgNb209 (perovskite, PMN) gets a near phase pure perovskite.

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Due to the high temperatures in the first reaction to columbite at 1000 ° C, however, only a moderately reactive Mg-niobate is obtained from the above-mentioned mixed oxides, so that the subsequent reaction with PbO only results in success at higher temperatures (> 800 ° C). This ceramic-prepared perovskite powder can only be sintered at higher temperatures during further processing In order to obtain good dielectric properties here at the same time, sintering temperatures of at least 1200 ° C are necessary.

Wet chemical methods have been found to be advantageous in the preparation of perovskites. Thus, in J. Am. Ceram. Soc. 72 (8), 1335-1357 (1989). the hydrolysis of an alkoxide mixture, described in EP-A-29991, the co-precipitation from an alcoholic oxalic acid solution. From Advanced in Ceramics, vol. 21, 91 ~ 98 (1987), the calcination of a gel is known, which is derived from NbCl5 resp. Nb (0R) 5 and metal-15 salts by addition of H 2 O 2 and citric acid were prepared. As a rule, highly reactive precursors are obtained by wet chemical processes which are converted to the desired perovskite even at low temperatures. Moreover, the sintering properties of these very fine powders have also clearly improved compared to the ceramic-prepared powders. However, in order to obtain high dielectric constants with these wet chemically prepared powders, sintering must be performed at temperatures> 1000 ° C. In addition, these wet chemical processes are not economical. For example, the alkoxide process has the drawback that the preparation and handling of the starting materials is very difficult.

In order to obtain materials which sinter at a low temperature (> 1000 ° C) and at the same time have a very high dielectric constant at room temperature, a series of formulations have been developed which contain several other compounds besides the base material PMN. Thus, in US-A-287,075, a formulation consists of lead iron niobate, lead magnesium niobate and lead magnesium tungstate, however additives such as lead manganese niobate, lithium oxide, chromium oxide and / or cerium oxide are still necessary. JP-A-57 ~ 208.004 describes a composition consisting of lead magnesium niobate, cadmium titanate, lead iron tungstate with additives of manganese oxide, cerium oxide, chromium oxide and / or cobalt oxide. According to US-A-5.01I.803, in addition to lead magnesium niobate, lead iron niobate and lead iron tungstate are also used, as well as additives 10013993 such as cadmium oxide, titanium oxide, cerium oxide and / or manganese oxide. 2% sintering aid is then added to this total mass. All aforementioned materials are ceramic compositions in which the base material PMN is present in less than 95% by weight.

Additives such as other perovskite compounds, dopants and / or sintering aids change the properties of the pure perovskite compounds, such as lead magnesium niobate or barium magnesium tantalate, more or less strongly. Thus, the aforementioned additive can, for example, drastically change the Curie temperature and thereby the application temperature of the materials. Compounds such as lead iron niobate lead to a decrease in the insulation resistance, while lead magnesium tungstate as well as sintering aids decrease the dielectric constant. At the same time, strange phases may occur in addition to the desired perovskites. The more additives added to the pure perovskite system, the more difficult or greater the effort to obtain homogeneous material mixtures. All this generally leads to a deterioration of the dielectric properties, so that the potential properties of the pure materials are not fully utilized.

Thus, the object of this invention is to provide highly reactive metal niobates and / or tantalates that can be processed into low temperature sintering ceramics with good dielectric properties.

Products that meet these requirements have now been found. These are highly reactive metal niobates and / or tantalates with the general composition Me (II) A206 resp. MeilIIJAOi ,, where A = Nb and Ta, and Me = Mg, Fe, Co, Ni, Cr, Mn, Cd, Cu and / or Zn, which contain an additive of Li, Na and / or K, the content of the additive is 0.1 to 20 mol #. In the case of magnesium niobate, the additive preferably consists of lithium niobate.

The subject of this invention is also a process for the preparation of the products according to the invention. This involves a process for the preparation of the metal niobates and / or tantalates by wet mixing of the respective metal oxides and niobium and / or tantalum components, drying and calcination, the niobium and / or tantalum component in the form of niobium and / or tantalum oxide hydrate.

The additives can be added before and / or during wet mixing. The Li, Na and / or K used therein is preferably added in the form of salts, hydroxides and / or oxides. The addition of lithium niobate and / or tantalate has been found to be particularly advantageous, with lithium in the form of a salt, hydroxide and / or oxide and the niobium and / or tantalum component in the form of niobium and / or tan language oxide hydrate (hydroxide) and / or acid are added.

Using the above-described method, homogenous material mixtures can be prepared in a very simple manner by means of a mixer, without grinding process, in which the dopant 10 is also distributed very homogeneously. The wet mixing can be carried out particularly advantageously in the range from 5 minutes to 90 minutes. When the metal components and the dopants in the form of carbonates, hydroxide carbonates, hydroxides and / or oxides are used, the end product is not contaminated with additional interfering anions. The dried material mixtures are advantageously calcined at 900 ° C to 1200 ° C, preferably 500 ° C to 1000 ° C, for 15 minutes to 6 hours.

The subject of this invention is also the further processing of the metal niobates and / or tantalates into perovskites of the general formula A (B'B ") 03, in which A = Pb and / or Ba, B '= Mg, Fe, Co, Ni, Cr, Mn, Cd, Ti, Zr and / or Zn and B "= Nb and / or Ta.

It has surprisingly been found that the metal niobates and / or tantalates doped according to the invention can be reacted with a lead component at very low temperatures. For example, a magnesium niobate mixed with Li, Na and / or K reacts after mixing with a lead component (PbO or Pb30i,) already at 600 ° C to the desired perovskite. The perovskite phase content is already 30% at a calcination temperature of 650 ° C. To date, no powders have been known which already convert perovskite at such low temperatures. Thus, the reactivity of the powders according to the invention is even superior to that of powders prepared wet-chemically.

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Table A

% perovskite content after calcination at 5 --------

Together- Method 600eC 650eC 700eC 800eC 900eC 1000'C

theorem P + M + N * Direct synthesis (1) - - - 68.4 74 76.3 10 -------- P + M + N * Sol-Gel (2) - - 9 98 P + M + N Sol-Gel (3) '45 ~ 60 '80 '95 '98 15 P + MN * Columbite (1) 98.9 98.5 98.2 P + MN ** HCST 3.4 90 94 99

Calcination Time: * 4 hours or more, ** 2 hours 20 (1) J. Am. Ceram. Soc., 67 (5) 311-315 (1984) (2) Ceram. Trans. 1.182-189 (1988) (3) Advanced in ceramics, 21, 91 ~ 98 (1987)

Due to the low calcination temperatures, the perovskites obtained are extremely fine, so that they can be further processed immediately. In all other processes known so far, the perovskite powders are ground for a fairly long time before they are further processed into ceramic. The powders are again contaminated with foreign elements, whereby the sinter and dielectric properties deteriorate again.

The high reactivity of the metal niobates and / or tantalates according to the invention is surprisingly also transferred to the perovskite powders obtained after the reaction. For example, lead magnesium niobates can be sintered at extremely low temperatures to, for example, dense ceramic. Densities greater than 952 are reached as early as 850eC / 2 hours. Surprisingly, the dielectric constants for PMN ceramic are very high at these extremely low sintering temperatures. At a measuring frequency of 100 kHz, PMN ceramics - sintered at 850 ° C - at 25 ° C, for example, DK values higher than 9000 40 are reached.

Sintered powders can also be prepared via sol-gel methods. However, the ceramics prepared by sol-gel methods show acceptable dielectric properties only at sintering temperatures> 1000 ° C. The dielectric properties can be improved if the sol-gel powders are hot pressed. However, these powders are in no way comparable to the powders according to the invention with regard to the dielectric properties. This makes it possible to access sinter-active lead perovskite powders for the first time, containing more than 95%, preferably 98%, of the basic components and already at temperatures clearly below 1000 ° C to dense ceramics with exceptionally good dielectric sintering properties (see Tables C to E).

10 Table B

Together- Method DK-max Sinter-om Measurement frequency theorems 15 PMN Columbite (1) 14,000 1270 ° C 100 kHz PMN Columbite (1) I5.9OO 1270 ° C 100 kHz PMN Columbite (1) 18,200 1270 ° C 100 kHz 20 ----- PMN Columbite (1) 16,400 1300 ° C 100 kHz PMN I5.9OO 60 kHz single crystal 25 ----- PMN Sol gel (4) 2992 900 ° C 1 kHz PMN Sol gel (4) 9369 1000 ° C 1 kHz 30 PMN Sol gel (4) 14,550 1100 ° C 1 kHz PMN Sol gel (4) 15-374 1200 ° C 1 kHz PMN Sol gel (4) 15,885 1250 ° C 1 kHz 35-- --- PMN (5) Hot pressed 6400 825 ° C 1 kHz 25 MPa PMN (5) Hot pressed 11,200 890 ° C 1 kHz 40 18 MPa PMN (5) 11,200 900 ° C 1 kHz PMN (5) 15,400 950 ° C 1 kHz 45 ----- PMN (5) 16,600 1050 ° C 1 kHz (1) J. Am. Ceram. Soc., 67, 3H "315 (1984) (4) Feroelectrics, Letters, 11, 137 ~ 144 (1990) 50 (5) J-Mater. Res. 5.2902-2909 (1990) 1 0 0 1 3 S 9 7

The invention is explained below by way of examples, without being limited thereto.

Example I

8 kg of filter-moist niobium oxide hydrate (hydroxide) with an Nb content of 24.4% was diluted with 3 l of water and mixed with 980 g of magnesium hydroxide carbonate. This suspension was homogenized in a Thyssen-Henschel mixer for 15 minutes at 2000 rpm. The resulting paste was distributed. Part of it was homogenized for another 15 minutes. Another part was mixed with 0.5% by weight, based on the calcined end product, of a metal component and also homogenized in the Thyssen-Henschel mixer for an additional 15 minutes. The thickened material mixtures - doped and undoped - were dried at 105 ° C and then calcined at 1000 ° C for 2 hours. The magnesium niobates were then mixed with the corresponding stoichiometric amount of Pb30 * and homogenized in a ball mill for 2 hours with the addition of water.

After drying at 105 ° C, the mixtures were calcined at different temperatures. X-ray diffraction analysis showed that the desired perovskite was already formed at 600 ° C. At 650 ° C / 2 hours, the perovskite content is already 90% (see Table A), regardless of which addition is chosen.

The perovskites obtained at 800 ° C were pressed into tablets (dia-25 meters 10 mm / height 1.5 mm) and sintered for 2 hours at different temperatures under normal atmospheric conditions. The dielectric properties of this ceramic were measured. For all sintered samples, the loss factor tan δ <200 -ΙΟ '* 1. Curie temperature was similar for all tests performed here. The 30 dielectric constants are shown in the following tables.

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Table C

Dielectric properties of PMN and Li20-PMN ceramics (additive 10 mol *) 5 Sinter-to-DK 25 ° C Density [g / cm3] DK 25 ° C Density [g / cm3] conditions PMN PMN PMN + Li20 PMN + Li20 2 hours / 850 not closed 8621 7.7 10 2 hours / 1000 7271 8.02 952 * 4 7.8 2 hours / 1200 99 * 46 7.96 8206 7.5

Theoretical density of PMN: 8.12 g / cm2 15

Table · d

Dielectric properties of PMN and LiNb03-PMN ceramics (additive 0.5 mol *) 20 Sinter-om DK 25 ° C Density [g / cm3] DK 25 ° C Density [g / cm3]

PMN PMN PMN + LN PMN + LN

2 hours / 850 not closed 12. * 461 7.9 25 2 hours / 900 not closed 12.9 * 42 7.91 2 hours / 1000 8665 8.0 13-255 7.96 2 hours / 1100 II.251 8.0 12,880 7.95 30 ------- 2 hours / 1200 11.19 * 4 7.88 11,807 7.83

Theoretical density of PMN: 8.12 g / cm2 Table E

Dielectric properties of PMN and K20-PMN ceramics (2 molji additive)

Sintered-DK 25 ° C Density [g / cm3] DK 25 ° C Density [g / cm3] * 40 settings PMN PMN PMN + K20 PMN + K20 2 hours / 850 not closed 8955 7.88 2 hours / 1000 9 * 40 * 4 7.93 9632 7.91 * 45 ------- 2 hours / 1200 11.865 7.90 8893 7.73

Theoretical density of PMN: 8.12 g / cm2 1001399

Claims (15)

1. Metal niobates and / or tantalates with the general composition Me (II) A20è, respectively. Μθ (ΙΙΙ) ΑΟλ, where A = Nb and / or Ta and Me = Mg, Fe, Co, Ni, Cr, Mn, Cd and or Zn, characterized in that they contain 0.1 to 20 mol% Li, Na and / or K. Metal niobates and / or tantalates according to claim 1, characterized in that the additive in magnesium niobate is lithium niobate. 10 Process for the preparation of metal niobates and / or tantalates according to claim 1 or 2 by wet mixing of the corresponding metal oxides and niobium and / or tantalum components, drying and calcination, characterized in that the niobium and / or tantalum components in the form of niobium and / or tantalum oxide hydrate and / or acid are used. Process according to claim 3, characterized in that the additives are used in the form of Li, Na and / or K salts, hydroxides and / or oxides. Process according to claim 3 or k, characterized in that the additive is lithium niobate and / or tantalate. Process according to one or more of claims 3 to 5, characterized in that the lithium components in the form of salts, hydroxides and / or oxides and the corresponding equivalent amount of the niobium and / or tantalum component in the form of niobium and / or tantalum oxide hydrates (hydroxides) and / or acids are used. Process according to one or more of claims 3 to 6, characterized in that the addition is 0.1 to 20 mol #. Process according to one or more of claims 3 to 7, characterized in that the wet mixing is carried out in the range of 5 to 90 minutes and 15 minutes to 6 hours at temperatures in the range of AOO'C. up to 1200 ° C, preferably 500 ° C to 1000 ° C, 10 0 1 3 9 9 is calcined. Process for the further processing of the metal niobates and / or tantalates according to one or more of claims 1 to 8 into perovskites of the general formula A (B'B ") 03, wherein A = Pb and / or Ba , B '= Mg, Fe, Co, Ni, Cr, Mn, Cd, Ti, Zr and / or Zn and B "= Nb and / or Ta. 10. Process according to claim 9, characterized in that the metal niobates and / or tantalates are mixed with a lead and / or barium component for 15 minutes to 24 hours, preferably 30 minutes to 6 hours. 11. Process according to claim 9 or 10, characterized in that 15 minutes to 6 hours are calcined at temperatures in the range from 400 ° C to 1100 ° C, preferably below 900 ° C. A method according to any one of claims 9 to 11, characterized in. that the perovskite obtained contains at least 95%, preferably> 20 & 9%, of the base component. A method according to any of claims 9 to 12, wherein the perovskite has the general formula Pb3Me (II) Nb209, respectively. Pb2Me (III) Nb06 is characterized in that the perovskite is sintered for 15 minutes to 10 hours at temperatures ranging from 700 ° C to 1300 ° C, preferably below 1000 ° C. Lead perovskite ceramic according to claim 13, characterized in. that the dielectric constant at 23 ° C at a measuring frequency of 100 kHz is more than 10,000. Lead perovskite ceramic according to claims 13 and 14, characterized in that it has a density greater than 95% of the theoretical density at sintering temperatures below 900 ° C. 1001399